KR20230054345A - Laundary treating apparatus - Google Patents

Abstract

The present invention relates to a clothing treatment apparatus wherein washing water injected toward the inside of a drum is injected while having various angles to be evenly injected to laundry accommodated in the drum. The clothing treatment apparatus comprises: a main body; a tub installed in the main body, and installed to accommodate washing water; a drum rotatably installed in the tub, and accommodating laundry; a gasket installed on the front surface of the tub, and having a plurality of nozzles for injecting water into the drum; a drain pump installed on a lower portion of the tub to move washing water discharged from the tub toward the tub; and annular flow paths fixed and installed on the gasket, and moving washing water entering by the drain pump to the nozzles. A plurality of the annular flow paths are separated and installed along the outer circumference of the gasket to move washing water entering from the drain pump in different directions.

Description

Clothes processing device {LAUNDARY TREATING APPARATUS}

The present invention relates to a laundry treatment apparatus capable of spraying circulated water discharged from a tub into a drum.

A laundry treatment device is a device that removes contamination from laundry by inserting clothes, bedding, etc. (hereinafter, referred to as laundry) into a drum. The laundry treatment apparatus can perform processes such as washing, rinsing, spin-drying, and drying, and is divided into a top loading method and a front loading method based on a method of inputting laundry. In general, front-loading washing machines are referred to as drum washing machines.

Such a drum washing machine (hereinafter, referred to as a laundry treatment device) includes a main body forming an exterior, a tub accommodated inside the main body, and a drum rotatably mounted inside the tub and into which laundry is put. When the drum is rotated by the motor in a state where wash water is supplied to the laundry stored in the drum, contaminants attached to the laundry can be removed by friction between the laundry and the drum or the wash water.

It is common to have a structure in which water discharged from the tub of the laundry treatment apparatus is circulated using a circulation pump and the circulated water is sprayed into the drum through a nozzle. However, conventional laundry treatment apparatuses typically have only one or two nozzles, so that the spray direction of wash water sprayed into the drum is limited, so that the laundry contained in the drum cannot be evenly sprayed.

In addition, the conventional laundry treatment apparatus has a structure in which a circulation pipe is connected to a circulation pump and wash water moved by the circulation pump is supplied to the nozzle through a connector connecting the nozzle and the circulation pipe. In this case, the circulation pump is connected to the circulation pump. Since the circulation tube and the guide tube connected to the circulation tube are separately required, the structure of the product is complicated and the manufacturing process is increased.

Therefore, there is a need for a laundry treatment device that has a relatively simple structure, a simple manufacturing process, and can spray wash water into the drum at various angles.

One object of the present invention is to provide a structure of a laundry treatment apparatus in which wash water sprayed towards the inside of a drum can be sprayed at various angles to evenly spray laundry accommodated in a drum.

Another object of the present invention is to provide a laundry treatment apparatus capable of injecting water circulated from a drain pump into an annular flow path that is installed separately from each other and spraying wash water into a drum through nozzles disposed at different heights on a gasket. to provide structure.

Another object of the present invention is a structure of a laundry treatment apparatus in which the flow rate of wash water sprayed through each nozzle can be varied and the wash water sprayed from each nozzle can be evenly sprayed even when a large amount of laundry is put into the drum. is to provide

In order to achieve the object of the present invention, a laundry treatment apparatus according to the present invention includes a main body, a tub installed inside the main body and installed to receive wash water, and rotatably installed inside the tub. a drum accommodating the tub, a gasket installed on the front side of the tub and having a plurality of nozzles for injecting water into the drum, and a gasket installed on the lower portion of the tub to discharge wash water discharged from the tub into the tub. and an annular flow path fixed to the gasket and moving wash water introduced by the drain pump to each of the nozzles, wherein a plurality of annular flow paths are provided along an outer circumference of the gasket. Separately installed, the washing water introduced from the drain pump can be moved in different directions.

At this time, the annular flow path may protrude toward the gasket from an inner surface and be inserted into the gasket, and may include a plurality of nozzle water supply ports for supplying wash water to each of the nozzles.

In addition, in the annular flow path, a curved portion is formed in a direction away from the outer surface of the gasket at a position corresponding to the nozzle inlet pipe, and each nozzle water supply port is formed to protrude from the curved portion in a direction toward the nozzle inlet pipe. It can be done.

In addition, a plurality of balancers having a constant weight may be installed on the front surface of the tub along the circumference of the inlet of the tub, and each balancer may be installed outside the annular flow path.

In addition, the annular flow path includes a first annular flow path installed on one side with respect to the heat supply part formed on the top of the gasket and a second annular flow path installed on the other side based on the heat supply part and spaced apart from the first annular flow path. It may be made to include an annular flow path.

In addition, the first annular flow path and the second annular flow path may communicate with the distribution pipe so that wash water discharged from the circulation port formed in the drain pump is separately supplied with the same flow rate.

In order to achieve the above object of the present invention, in the laundry treatment apparatus according to the present invention, wash water may be sprayed toward the inside of the drum at various angles by means of the annular passages installed separately from each other on the outside of the gasket.

In addition, since a plurality of nozzle water supply ports are installed in the annular passage at regular intervals, the water circulated from the drain pump is sprayed into the drum through the nozzle formed in the gasket through each annular passage coupled through the distribution pipe, You can reach deep places.

In addition, since the annular flow path is installed outside the gasket, it is easy to install and separate, and has the advantage of simplifying the manufacturing process for installing it.

In addition, the annular flow passages installed separately from each other may be connected to different circulation passages formed in the drain pump, so that the flow rate of wash water sprayed through the nozzle may be varied.

1 is a perspective view showing the internal structure of a laundry treatment apparatus according to the present invention.
Fig. 2 is a front view showing a front view of the laundry treatment apparatus according to the present invention.
3 is a view showing how an annular flow path is installed outside the gasket.
Figure 4a is a side view of the gasket of Figure 3 viewed from the side.
4B is a cross-sectional view of the gasket of FIG. 3 cut away.
5A is a perspective view showing an annular flow path according to the present invention.
5B is a conceptual view of the first annular flow path viewed from the side.
6 is a conceptual diagram illustrating a state in which a first annular flow path and a second annular flow path are installed along an outer circumferential portion of a gasket, according to another embodiment of the present invention.
Fig. 7 is a front view of a laundry treatment apparatus according to still another embodiment of the present invention.
FIG. 8 is a conceptual diagram showing how an annular flow path installed in a gasket in the laundry treatment apparatus of FIG. 7 is connected to a drain pump.
FIG. 9 is a perspective view showing the first annular flow path and the second annular flow path, showing the appearance of the annular flow path according to the present embodiment.
10 shows a modified embodiment of the annular flow path, and is a conceptual diagram illustrating a state in which a first annular flow path and a second annular flow path are installed along an outer circumferential portion of a gasket.

Hereinafter, the laundry treatment apparatus according to the present invention will be described in more detail with reference to the drawings.

In this specification, singular expressions include plural expressions unless the context clearly dictates otherwise.

In describing the embodiments disclosed in this specification, if it is determined that a detailed description of a related known technology may obscure the gist of the embodiment disclosed in this specification, the detailed description thereof will be omitted.

The accompanying drawings are only for easy understanding of the embodiments disclosed in this specification, and the technical idea disclosed in this specification is not limited by the accompanying drawings, and all changes and equivalents included in the spirit and technical scope of the present invention are included. It should be understood to include water or substitutes.

1 is a perspective view showing the overall structure of a laundry treatment apparatus 100 according to the present invention.

The laundry treatment apparatus 100 includes a main body 110, a tub 120, a drum 130, a gasket 150, and an annular flow path 140.

The main body 110 forms the outer appearance and skeleton of the laundry treatment device 100, and an inlet for putting laundry is formed in the front part, and a door is rotatable in the front part of the main body 110 to open and close the inlet. can be installed

The tub 120 has a storage space for storing wash water therein, and an opening (not shown) is formed at the front so as to communicate with the inlet of the main body 110 . A gasket 150 is installed at the front of the tub 120 to connect the opening and the inlet of the main body 110 . The tub 120 may have a cylindrical shape. A drain hole (not shown) is formed on the bottom of the tub 120, and a bellows-shaped drain pipe (not shown) is connected to the drain hole so that wash water is drained from the tub 120 through the drain hole.

The detergent input unit 113 is connected to a water supply pipe (not shown) so that water supplied from the outside flows into the storage unit and the water and detergent are mixed. The detergent input unit 113 accommodates additives such as detergent or fabric softener, and communicates with the tub 120 to supply water together with the supplied water to the inside of the tub 120 so that it can be supplied to the laundry.

The drum 130 is rotatably installed inside the tub 120 and has an accommodation space therein to accommodate laundry. The drum 130 has a plurality of through-holes (not shown) through which wash water of the tub 120 may flow into the drum 130 . In addition, a plurality of lifters 131 are installed inside the drum 130 so that when the drum 130 rotates, the laundry is rotated upward along the circumferential direction and then dropped from the top to the bottom to improve washing performance. .

The gasket 150 is to prevent water contained in the tub 120 from leaking. It is formed in a tubular shape between the rear ends. The gasket 150 may be made of a flexible material having elasticity, and may be made of, for example, natural rubber or synthetic resin.

Since the clothes handling apparatus 100 according to the present invention can perform a drying function as well as a washing function, hot air is blown through the drum 130 to dry the laundry stored in the drum 130 after washing is completed on the upper part of the gasket 150. A heat supply unit 121 for supply is formed. In the case of the laundry treatment device 100 capable of only washing, the heat supply unit 121 to the gasket 150 may not be necessary. In the present specification, a laundry and drying apparatus in which the heat supply unit 121 is formed in the gasket 150 will be described as an example.

A driving unit (not shown) for driving the drum 130 is mounted on the rear surface of the tub 120 . The driving unit may be composed of a motor, and may include a stator (not shown) and a rotor (not shown) generating electromagnetic force by electrical interaction, and a rotation shaft (not shown) coupled to the rotor and rotating together with the rotor. there is.

A drain pump 135 is installed on the base 111 located below the main body 110. The drainage pump 135 is installed below the tub 120 and serves to move water discharged from the tub 120 toward the tub 120 again.

The drain pump 135 may be configured to include a pump casing (not shown) and an impeller (not shown), and the motor constituting the drain pump 135 is a variable speed motor capable of controlling rotational speed, and is a brushless direct (BLDC) motor. Current Motor) motor. The drainage pump 135 includes a BLDC motor capable of rotating in both directions, and discharges washing water through a drainage passage (not shown) when rotating in one direction, and a circulation passage 136 when rotating in the other direction. Through this, it is possible to circulate the wash water into the tub 120. That is, the drainage pump 135 may also serve as a circulation pump. Hereinafter, the drain pump 135 is also referred to as the pump 135.

A drain hole is formed on one side of the pump casing (not shown), and wash water discharged through the drain hole can be discharged to the outside through the drain pipe. A circulation hole 135a is formed on the other side of the pump casing, and the washing water discharged from the drum 130 according to the driving of the impeller of the drain pump 135 returns to the inside of the drum 130 through the circulation hole 135a. can be cycled. The circulation hole (135a) is connected to a circulation hose (not shown), and the circulation hose is made to extend upward toward the lower part of the drum (130). The drainage pump 135 can simultaneously serve as circulation and drainage by rotating the impeller in both directions.

The laundry treatment apparatus 100 includes a controller (not shown), and serves to control the speed and direction of the drain pump 135 together with the overall driving of the laundry treatment apparatus 100.

In addition, the laundry treatment apparatus 100 according to the present invention is fixedly installed to the gasket 150, and water introduced by the drainage pump 135 passes through each nozzle 151 formed in the gasket 150 to the drum 130. ) includes an annular flow path 140 for injecting into the structure. A detailed description of this will be described later.

FIG. 2 shows a front view of the laundry treatment apparatus 100 according to the present invention, and FIG. 3 is a view showing the annular flow path 140 installed outside the gasket 150 . As shown in FIGS. 2, 3, 5A, and 6 to 10, the annular flow path 140 does not mean only a flow path having a perfect circular annular shape, but extends along the gaskets 150 and 250. It is meant to include a flow path having an arc shape. Hereinafter, the 'annular flow path' is also referred to as a 'flow path', and the 'first and second annular flow paths' are also referred to as 'first and second flow paths'.

In front of the tub 120, a balancer 133 is positioned along the circumference of the inlet of the tub 120. The balancer 133 serves to reduce vibration of the tub 120 and has a constant weight. As shown in FIG. 2, the balancer 133 may be composed of a plurality, and when viewed from the front of the tub 120, the first balancer 133a positioned on the left side and the second balancer 133b positioned on the right side may consist of

Since the first balancer 133a and the second balancer 133b can be installed separately into two on the left and right sides by the annular flow passages 141 and 142 that are separately installed in the gasket 150, the number of balancers installed can be reduced. can be reduced, which has the effect of reducing manufacturing costs and labor.

In the laundry treatment apparatus 100 according to the present invention, the gasket 150 is fixedly installed, and water introduced by the drainage pump 135 is introduced into the drum 130 through each nozzle 151 formed in the gasket 150. It includes an annular flow path 140 for injection. The annular flow path 140 may be composed of two different annular flow paths 140 installed spaced apart from each other and positioned to face each other. Each annular flow path 140 may be installed separately from each other along the outer circumference of the gasket 150 so that water introduced from the drain pump 135 can move in different directions.

On the outer circumference of the gasket 150, two different annular flow passages 140 are installed to face each other. Each annular flow path 140 is fixedly installed on the outer circumferential surface of the gasket 150, and the balancer 133 is installed on the tub 120 to be positioned outside the annular flow path 140.

The annular flow path 140 is made to communicate with the circulation flow path 136 extending from the bottom to the top of the laundry treatment apparatus 100 by the drain pump 135, and to spray wash water through the respective nozzles 151. do. That is, the circulation passage 136 is connected to the pump 135 and extends upward.

The annular flow path 140 includes a first annular flow path 141 and a second annular flow path 142 installed to be separated from each other on the left and right sides of the distribution pipe 143 . The first annular flow path 141 is located on the left side of the gasket 150 relative to the heat supply unit 121, and the second annular flow path 142 is located on the right side relative to the heat supply unit 121.

Wash water moving from the drain pump 135 is branched toward the first annular flow path 141 and the second annular flow path 142 through the distribution pipe 143, respectively, and passes through the first annular flow path 141 and the second annular flow path. It moves along the inside of (142). The first annular flow path 141 and the second annular flow path 142 are separately supplied with the same flow rate of wash water discharged from the circulation port 135a formed in the drain pump 135 through the distribution pipe 143. make it possible When water is supplied in one direction from the drainage pump 135 and supplied to the first annular flow path 141 and the second annular flow path 142, there is an advantage in that a sufficient input flow rate can be secured, and each annular flow path 141 and 142 Since the balancer can be installed to correspond to, there is an advantage that cost can be reduced by reducing the number of balancers installed.

The first annular flow path 141 and the second annular flow path 142 are formed to protrude toward the gasket 150 and to be inserted into the gasket 150, and have a plurality of nozzles for supplying wash water toward each nozzle 151. It includes nozzle water supply ports 141a and 142a. The nozzle water supply port 141a protruding from the first flow path 141 is also called the first nozzle water supply port 141a, and the nozzle water supply port 142a protruding from the second flow path 142 is also called the second nozzle water supply port 142a. do.

Since the laundry treatment apparatus 100 according to the present invention can spray wash water into the drum 130 as many times as the number of nozzle water supply ports 141a and 142a formed in each annular flow path 140, the wash water is supplied at various angles. is sprayed into the drum 130 to wet the stored laundry, so that washing performance can be improved. That is, multi-spraying of washing water at various angles is possible through the nozzle.

A plurality of nozzles 151 for spraying wash water into the drum 130 are formed on the gasket 150 . Nozzles 151 are formed in the gasket 150 as many as the total number of nozzle water supply ports 141a and 142a formed in each of the annular flow passages 141 and 142 . The nozzle water supply ports 141a and 142a formed in each of the annular passages 141 and 142 are inserted into the nozzle 151, and the wash water moving through each of the annular passages 141 and 142 is directed to the nozzle 151. It is supplied so that it can be sprayed into the drum 130.

Each nozzle 151 is made so that the nozzle water supply port 141a is inserted and sprays the wash water supplied through the nozzle inlet pipe 151a through which wash water flows into the drum 130. It includes a nozzle head (151b) for. A nozzle water supply port 141a is inserted into the nozzle inlet pipe 151a, and washing water moves from the nozzle water supply port 141a so that the washing water can be sprayed into the drum 130 through the nozzle head 151b. At this time, the wash water sprayed from each nozzle head 151b is sprayed into the drum 130 at an angle of approximately 45 to 55 degrees.

FIG. 4A is a view of the gasket 150 of FIG. 3 viewed from one side, and FIG. 4B is a cross-sectional view of the gasket 150 where the first annular flow path 141 is located.

The gasket 150 is installed between the tub 120 and the inlet of the main body 110 and is made of a material having an annular elastic force. As described above, an annular flow path 140 is installed outside the gasket 150 . In the nozzle inlet pipe 151a of the nozzle 151, the nozzle water supply ports 141a formed in the annular flow passages 141 and 142 are positioned to correspond to each other so that the washing water passes through the nozzle head 151b to the inside of the drum 130. will be sprayed with

Referring to FIG. 4B , a seating groove 152 may be formed on an outer circumferential surface of the gasket 150 to be recessed from the outside to the inside. The seating groove 152 is formed along the outer circumferential surface of the gasket 150 , and the first annular flow path 141 can be positioned in the seating groove 152 . Since the balancer 133 is located outside the first annular flow path 141, the annular flow path 140 will be located between the balancer 133 and the gasket 150.

The gasket 150 may include a folding portion 153 that is folded or unfolded in response to the movement of the drum 130, and a seating groove 152 is formed at one end of the folding portion 153 to form each annular flow path ( 141, 142) can be positioned. 4B shows a state in which the first annular flow path 141 is positioned in the seating groove 152.

The width of the seating groove 152 may be made to have a width corresponding to the width of each annular passage 141, 142, and when each annular passage 141, 142 is located in the seating groove 152, each It is preferable that the seating groove 152 has a groove having a greater depth than the annular passage 140 so that the annular passages 141 and 142 do not protrude outward from the gasket 150 . If each of the annular flow passages 141 and 142 do not protrude from the gasket 150, the influence of external impact on each of the annular flow passages 141 and 142 will be limited and aesthetically pleasing.

5A is a perspective view showing an annular flow path 140 according to the present invention, and FIG. 5B shows a view of the first annular flow path 141 viewed from the side.

As described above, the annular flow path 140 is configured to include a first annular flow path 141 and a second annular flow path 142 installed along the outside of the gasket 150 . Each of the annular passages 140 are connected to different positions of the distribution pipe 143, and wash water moving along the circulation passage may be supplied to the inside of each of the annular passages 141 and 142 via the distribution pipe 143. there will be

Each of the annular flow passages 141 and 142 protrude toward the gasket 150, and nozzle water supply ports 141a and 141b are formed to allow washing water to move toward the nozzle 151. As shown in FIG. 5 , the nozzle water supply ports 141a formed in the first annular flow path 141 are formed at different positions of the first annular flow path 141 . Two nozzle water supply ports 141a may be formed in the first annular flow path 141 .

Similarly, two nozzle water supply ports 141b may be formed in the second annular passage 142, and a total of four nozzle water supply ports formed on the premise of the first annular passage 141 and the second annular passage 142 The (141a, 141b) supplies wash water to the nozzle 151 of the gasket 150, so that the wash water can be sprayed into the drum 130 at four locations through the nozzle head. In addition, when atomization nozzles (not shown) are installed instead of the heat supply unit 121 for drying, it may be possible to spray wash water into the drum 130 at five locations.

Between the two nozzle water supply ports 141a respectively formed in the first annular flow path 141 and the second annular flow path 142 may be disposed to have an interval of about 55 degrees with respect to the center of the drum 130. .

However, the number of nozzles 151 and nozzle water supply ports 141a and 141b is not limited, but can be made to have various numbers, and the angle between each nozzle water supply port 141a can be arbitrarily selected by the user. .

In the first annular flow path 141 and the second annular flow path 142, a bent portion 141b is formed in a direction away from the outer surface of the gasket 150 at a position corresponding to the nozzle inlet pipe 151a, and the bent portion 141b ) is formed, a nozzle water supply port 141a is formed and positioned so as to be fitted into the nozzle inlet pipe 151a.

In each of the annular flow passages 141 and 142, nozzle water supply ports 141a are formed to protrude toward the nozzle 151 at regular intervals. Also, at one end of the first annular flow path 141 and the second annular flow path 142, coupling portions 141c and 142c inserted into and coupled to one side of the distribution pipe 143 are formed. The coupling portions 141c and 142c are formed in a protruding cylindrical shape.

As shown in FIG. 5B, the inner cross-sectional area of the first annular flow path 141 becomes smaller from the bottom to the top. Since the first annular flow path 141 is located higher from the ground from the lower part to the upper part, in order to compensate for the water pressure so that the washing water moves toward the nozzle 151 with the same pressure, the first annular flow path 141 is higher than the lower part of the first annular flow path 141. The inner cross-sectional area at the top will be made smaller.

That is, the first annular flow path 141 may have a shape in which the width Db at the top is smaller than the width Da at the bottom where the coupling portion 141c is located, and is tapered toward the top.

FIG. 6 shows another embodiment of the present invention in which the first annular flow path 141 and the second annular flow path 142 are installed along the outer circumference of the gasket 150 .

As described above, the annular flow path 140 includes a first annular flow path 141 and a second annular flow path 142 installed on the left and right sides of the heat supply unit 121 . One ends of the first annular flow path 141 and the second annular flow path 142 are installed to communicate with one side of the distribution pipe 143 and extend from the bottom to the top along the outer circumference of the gasket 150 .

However, the first annular flow path 141 and the second annular flow path 142 may have different lengths, and may also have different numbers of nozzle water supply ports 141a. As shown in FIG. 6 , the first annular flow path 141 and the second annular flow path 142 may have shapes that are not symmetrical to each other. The first annular flow passage 141 has one end communicating with the distribution pipe 143 and the other end having a nozzle water supply port 141a to supply washing water to the nozzle 151 formed in the 12 o'clock direction of the gasket 150. . It is also possible that three nozzle water supply ports 141a are formed at regular intervals in the first annular flow passage 141 .

The second annular flow passage 142 has one end communicating with the distribution pipe 143, may be made to extend from the bottom to the top along the circumference of the gasket 150, and two nozzle water supply ports 142a are formed. can

In this case, a total of five nozzle water supply ports 141a and 142a formed by the first annular flow path 141 and the second annular flow path 142 are formed in the gasket 150, each of the five nozzle inlet pipes 151a It will be inserted into each of the nozzle head (151b) toward the drum 130 through the injection of washing water will be possible.

FIG. 7 is a view showing the appearance of a laundry treatment apparatus according to another embodiment of the present invention, and FIG. 8 shows a state in which the annular flow passages 241 and 242 installed in the gasket 250 are connected to the drain pump 235. it is a concept

The annular passages 241 and 242 are configured such that two different annular passages 241 and 242 face each other along the outer circumference of the gasket 250 . Each of the annular flow channels 241 and 242 may be installed separately from each other along the outer circumference of the gasket 250 so that water introduced from the drain pump 235 can move in different directions. Each of the annular flow passages 241 and 242 are fixed to the gasket 250, and wash water introduced by the drain pump 235 can be sprayed into the drum through each nozzle 251 formed in the gasket 250. do.

Each of the annular flow passages 241 and 242 are fixedly installed on the outer circumferential surface of the gasket 250, and the balancer 233 is fixed to the tub to be positioned outside the annular flow passage 241 and 242. Each annular flow path can separately receive wash water without interfering with each other.

However, in the laundry treatment apparatus according to the present embodiment, the first annular flow path 241 and the second annular flow path 242 extend from different circulation ports 235a formed in the drain pump 135, the circulation flow path 236a, 236b) and have a configuration made to communicate with each other. In addition, the balancers 233a, 233b, and 233c correspond to the first balancer 233a and the second balancer 233b, the first annular flow path 241 and the first It may be made to include a third balancer 233c installed under the gasket 250 so as not to interfere with the second annular flow path 242 .

The first annular flow path 241 and the second annular flow path 242 are formed to extend upward along the outer circumference of the gasket 250 from both sides of the lower portion of the gasket 250 . At this time, the inner cross-sectional areas of the first annular flow path 241 and the second annular flow path 242 have a tapered shape that becomes smaller towards the top of the gasket 250 for pressure compensation, as described above.

In addition, the first annular flow path 241 and the second annular flow path 242 protrude toward the gasket 250 and are inserted into the gasket 250 to supply wash water toward each nozzle 251. A plurality of nozzle water supply ports 241a and 242a are formed.

The annular passages 241 and 242 include a first annular passage 241 and a second annular passage 242 installed to be separated from each other on the left and right sides. The first annular flow path 241 is located on the left side of the gasket 250 relative to the heat supply unit 221, and the second annular flow path 242 is located on the right side relative to the heat supply unit 221.

Wash water may be discharged from different circulation ports 235a formed in the drain pump 235 and move toward the first annular flow path 241 and the second annular flow path 242 along the respective circulation flow paths 236a and 236b. there will be That is, it has a structure in which washing water is twin supplied toward the first annular passage 241 and the second annular passage 242 .

At this time, the first annular flow path 241 and the second annular flow path 242 communicate with each other through the circulation port 235a formed in the drain pump 235, so that the wash water discharged from the drain pump 235 has the same flow rate. so that they can be supplied separately from each other.

9 is a perspective view showing the appearance of the annular passages 241 and 242 according to the present embodiment, and the first annular passage 241 and the second annular passage 242 .

The annular passages 241 and 242 include a first annular passage 241 and a second annular passage 242 installed along the outside of the gasket 250 . Each of the annular flow passages 241 and 242 communicate with each other from the circulation port 235a of the drain pump 235, and wash water flowing out from the circulation port 235a of the drain pump 235 flows through the annular flow passage 241 and 242. allow it to move inside.

The first annular flow path 241 and the second annular flow path 242 protrude toward the gasket 250 and include nozzle water supply ports 241a and 242a through which washing water moves toward the nozzle 251 . For example, as shown in FIG. 9, each of the nozzle water supply ports 241a and 242a may be formed at different positions of the annular flow path 240, and the first annular flow path 241 and the second annular flow path 242 ) are formed, respectively, so that wash water can be sprayed into the drum 230 through a total of four nozzles 251 in the gasket 250. Between the two nozzle water supply ports 241a and 242a formed in the first annular flow path 241 and the second annular flow path 242 may be installed to have an interval of about 55 degrees with respect to the center of the drum 130. There will be.

The first annular flow path 241 and the second annular flow path 242 may be formed to be curved in a direction away from the outer surface of the gasket 250 at a position corresponding to the nozzle inlet pipe 251a. The nozzle water supply port 241a may protrude from a curved portion and be positioned so as to be inserted into the nozzle inlet pipe 251a.

Nozzle water supply ports 241a and 242a are formed to protrude toward the nozzle 251 at regular intervals in each of the annular flow passages 241 and 242 . Also, at one end of the first annular flow path 241 and the second annular flow path 242, coupling portions 241c and 242c are formed to couple one side to the circulation flow path 236, respectively. The coupling portions 24c and 242c are formed in a protruding cylindrical shape and are formed to face the outside of the gasket 150 .

10 shows a modified embodiment of the annular flow passages 241 and 242, and shows a state in which the first annular passage 241 and the second annular passage 242 are installed along the outer circumference of the gasket 250. .

As described above, each annular flow path 241 and 242 includes a first annular flow path 241 installed on the left side of the heat supply unit 221 and a second annular flow path 242 installed on the right side. One ends of the first annular flow path 241 and the second annular flow path 242 are installed to communicate with one side of the different circulation flow paths 236a and 236b, respectively. The first annular flow path 241 and the second annular flow path 242 are formed to extend from the bottom to the top along the outer circumference of the gasket 250 .

In addition, the first annular flow path 241 and the second annular flow path 242 may be formed to have different lengths, and different numbers of nozzle water supply ports 241a and 242a may be formed. As shown in FIG. 10, the first annular flow path 241 has one end provided with a coupling part 241c so as to communicate with the first circulation flow path 236a, and the other end formed in the 12 o'clock direction of the gasket 250. A nozzle water supply port 241a is provided to supply wash water to the nozzle 251 . That is, the first annular flow path 241 may have three nozzle water supply ports 241a formed at regular intervals, and the second annular flow path 242 may have two nozzle water supply ports 242a.

A total of five nozzle water supply ports 241a and 242a formed by the first annular flow path 241 and the second annular flow path 242 are inserted into each of the five nozzle inlet pipes 251a formed on the gasket 250, Washing water may be sprayed toward the inside of the drum 230 through the nozzle head 251b.

What has been described above is only the embodiments for implementing the laundry treatment apparatus according to the present invention, and the present invention is not limited to the above embodiments, and does not deviate from the gist of the present invention as claimed in the following claims. Anyone with ordinary knowledge in the field to which the present invention pertains to the extent that the technical spirit of the present invention is present to the extent that various changes can be made.

100: clothes handling device 110: main body
120: tub 130: drum
133: balancer 135: drain pump
140 annular flow path 141: first annular flow path
142: second annular flow path 143: distribution pipe
141a, 142a: nozzle water supply port 141b, 142b: bent portion
150: gasket 153: folding portion

Claims (1)

A main body having an inlet;
a tub having an opening communicating with the inlet and a storage space configured to store wash water;
a drum rotatably installed inside the tub and accommodating laundry;
a gasket connecting the inlet of the main body and the opening of the tub;
a plurality of nozzles provided on the gasket to inject water into the drum;
a pump installed below the tub to move wash water discharged from the tub to the plurality of nozzles;
a circulation passage connected to the pump and extending upward;
a first flow path connected to the circulation flow path and extending upward along a circumference of the gasket from an outside of the gasket; and
A plurality of first nozzle water supply ports protruding from the first passage toward the gasket and connected to the nozzle;
The first flow path includes a bent portion bent in a direction away from the gasket,
At least one of the plurality of first nozzle water supply ports protrudes from the bent portion.

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